Allocation of primitives to primitive blocks

ABSTRACT

An application sends primitives to a graphics processing system so that an image of a 3D scene can be rendered. The primitives are placed into primitive blocks for storage and retrieval from a parameter memory. Rather than simply placing the first primitives into a primitive block until the primitive block is full and then placing further primitives into the next primitive block, multiple primitive blocks can be “open” such that a primitive block allocation module can allocate primitives to one of the open primitive blocks to thereby sort the primitives into primitive blocks according to their spatial positions. By grouping primitives together into primitive blocks in accordance with their spatial positions, the performance of a rasterization module can be improved. For example, in a tile-based rendering system this may mean that fewer primitive blocks need to be fetched by a hidden surface removal module in order to process a tile.

BACKGROUND

Graphics processing systems are used to process graphics data. For example, an application running on a computing system may need to render an image of a three dimensional (3D) scene for display to a user. The application can send graphics data, typically in the form of a sequence of primitives to a graphics processing system which can render the image of the scene in accordance with the primitives.

FIG. 1 shows some elements of a graphics processing system 100 which may be used to render an image of a 3D scene. The graphics processing system 100 comprises a graphics processing unit (GPU) 102 and two portions of memory 104 ₁ and 104 ₂. It is noted that the two portions of memory 104 ₁ and 104 ₂ may, or may not, be parts of the same physical memory, and typically both memories 104 ₁ and 104 ₂ are situated “off-chip”, i.e. not on the same chip as the GPU 102. Communication between the memories (104 ₁ and 104 ₂) and the GPU 102 may take place over a conventional communications bus in the system 100, as is known in the art.

In the example shown in FIG. 1, the graphics processing system 100 is a tile-based deferred rendering system, meaning that the rendering space of the system 100 is divided into a plurality of tiles and that hidden surface removal is performed on a primitive fragment prior to performing texturing and/or shading on the primitive fragment in order to render the scene. However, in other examples, graphics processing systems may be non tile-based and/or not deferred rendering systems. The GPU 102 comprises a geometry processing module 106, a tiling module 108 and a rasterization module 110, wherein the rasterization module 110 comprises a hidden surface removal (HSR) module 112 and a texturing/shading module 114. The graphics processing system 100 is arranged such that a sequence of primitives provided by an application is received at the geometry processing module 106. The geometry processing module 106 performs functions such as clipping and culling to remove primitives which do not fall into a visible view or rendering space of the computing system. The geometry processing module 106 may also project the primitives into screen-space. The geometry processing module 106 puts the received primitives into primitive blocks. Each primitive block has a header which includes state information (such as a depth compare mode, a blending state, a texture state, a primitive type, etc.) to describe how the primitives in the primitive block are to be rendered. There are many reasons to split the sequence of primitives into primitive blocks. For example, splitting the sequence of primitives into primitive blocks in this way is useful so that the primitives can be stored and fetched from memory in small, manageable blocks. Furthermore, there may be a limited number of vertices in each primitive block (e.g. up to 64 vertices in each primitive block), so indices of the vertices in a primitive block can be represented with a fixed number of bits, for example only 6 bits are needed for the indices when the primitive block stores up to 64 vertices. Therefore, splitting the sequence of primitives into primitive blocks will reduce the cost of vertex index data storage in computer graphics processing hardware. Furthermore, there are often many primitives which share the same state, so including these primitives in the same primitive block means that they can share the same state information in the header of the primitive block, which may reduce the total amount of state information needed for the primitives. Furthermore, splitting the sequence of primitives into primitive blocks allows for more opportunities to compress the primitive blocks before storing them in a memory. For example, if the first byte of all of the primitives in a primitive block are the same then the primitives can be compressed by storing the data for the first byte just once and an indication that this byte is to be used for every primitive within the primitive block. This is just one example of many ways in which primitive data within a primitive block can be compressed.

As a person skilled in the art will know, the sequence order of the incoming primitives can affect the way in which the scene is rendered. For example, if a plurality of overlapping primitives are translucent then the order in which they are processed will typically affect the way in which in the primitives are blended to form the rendered scene. Therefore, in order to maintain the sequence order of the incoming primitives, the geometry processing module 106 places them into primitive blocks without altering their sequence order. The primitives are initially put into a first primitive block and when the first primitive block is full then it can be output from the geometry processing module 106 and further incoming primitives can be placed into a new primitive block. In this way the sequence order of the primitives is maintained in the primitive blocks that are output from the geometry processing module 106. A primitive block may be considered to be “full” if the number of vertices in the primitive block is greater than or equal to a vertex threshold (e.g. the maximum number of vertices in a primitive block may be 64 or 256 to give two examples) and/or if the number of primitives in the primitive block is greater than or equal to a primitive threshold (e.g. the maximum number of primitives in a primitive block may be 128 or 512 to give two examples).

The primitive blocks which are output from the geometry processing module 106 are passed to the tiling module 108 which determines which primitives are present within each of the tiles of the rendering space of the graphics processing system 100. The tiling module 108 determines per-tile display lists which indicate which primitives are present within each of the tiles of the rendering space. The display lists and the primitive blocks are outputted from the tiling module 108 and stored in the memory 104 ₁. The rasterization block 110 fetches the display list for a tile and the primitive blocks relevant to that tile from the memory 104 ₁ and the HSR module 112 performs hidden surface removal to thereby remove fragments of primitives which are hidden in the scene. The remaining fragments are passed to the texturing/shading module 114 which performs texturing and/or shading on the fragments to determine pixel values of a rendered image which can be passed to the memory 104 ₂ for storage in a frame buffer. The rasterization block 110 processes each of the tiles and when the whole image has been rendered and stored in the memory 104 ₂, the image can be outputted from the graphics processing system 100 and, for example, displayed on a display.

SUMMARY

This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.

There is provided a method of allocating primitives to primitive blocks at a primitive block allocation module which includes a data store for storing a set of primitive blocks to which primitives can be allocated, the method comprising: receiving a sequence of primitives; and for each of the received primitives, if at least one primitive block is stored in the data store: (i) comparing an indication of a spatial position of the received primitive with at least one indication of a spatial position of the at least one primitive block stored in the data store; and (ii) allocating the received primitive to a primitive block based on the result of the comparison, such that the received primitive is allocated to a primitive block in accordance with its spatial position.

There is also provided a primitive block allocation module for allocating primitives to primitive blocks, the primitive block allocation module comprising: a data store configured to store a set of primitive blocks to which primitives can be allocated; and allocation logic configured to: (a) receive a sequence of primitives, and (b) for each of the received primitives, if at least one primitive block is stored in the data store: (i) compare an indication of a spatial position of the received primitive with at least one indication of a spatial position of the at least one primitive block stored in the data store, and (ii) allocate the received primitive to a primitive block based on the result of the comparison, to thereby allocate the received primitive to a primitive block in accordance with its spatial position.

There may also be provided computer readable code adapted to perform the steps of any of the methods described herein when the code is run on a computer. There may also be provided computer readable code for generating a graphics processing unit comprising the primitive block allocation module according to any of the examples described herein. The computer readable code may be encoded on a computer readable storage medium.

The above features may be combined as appropriate, as would be apparent to a skilled person, and may be combined with any of the aspects of the examples described herein.

BRIEF DESCRIPTION OF THE DRAWINGS

Examples will now be described in detail with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of a graphics processing system of the prior art;

FIG. 2 is a schematic diagram of a graphics processing system including a primitive block allocation module;

FIG. 3 is a flow chart illustrating a method of allocating primitives to primitive blocks at a primitive block allocation module;

FIG. 4 is a representation of a scene to be rendered;

FIG. 5 is a representation of a primitive block; and

FIG. 6 is a schematic diagram of a computer system.

The accompanying drawings illustrate various examples. The skilled person will appreciate that the illustrated element boundaries (e.g., boxes, groups of boxes, or other shapes) in the drawings represent one example of the boundaries. It may be that in some examples, one element may be designed as multiple elements or that multiple elements may be designed as one element. Common reference numerals are used throughout the figures, where appropriate, to indicate similar features.

DETAILED DESCRIPTION

In the system described above with reference to FIG. 1, the primitives are placed into a primitive block in the order that they are received by the graphics processing system 100, so that the sequence order of the primitives is maintained. The primitives may be distributed widely over a rendering space of the graphics processing system 100, but this distribution does not influence the order in which the primitives are placed into the primitive block. In particular, there may often be situations in which primitives with non-overlapping bounding boxes are included in the same primitive block. The inventors have realised that it may be beneficial to sort the primitives into primitive blocks according to their spatial positions, and that this is possible for non-overlapping primitives without causing problems due to changes in the sequence order of the primitives. That is, it is important to preserve the relative sequence order of primitives which overlap with each other, but it is not so important to preserve the relative sequence order of primitives which do not overlap with each other, and this flexibility in the relative ordering of non-overlapping primitives allows the primitives to be sorted into primitive blocks according to their spatial positions. As described in more detail below, by grouping primitives together into primitive blocks in accordance with their spatial positions, the performance of a HSR module and/or a texturing/shading module can be improved. For example, the cache coherency of the HSR module can be improved. As another example, in a tile-based rendering system, the HSR module may need to fetch fewer primitive blocks, thereby reducing the amount of primitive data that needs to be fetched by the HSR module.

Embodiments will now be described by way of example only.

FIG. 2 shows some elements of a graphics processing system 200 which may be used to render an image of a 3D scene. The graphics processing system 200 comprises a GPU 202 and two portions of memory 204 ₁ and 204 ₂. It is noted that the two portions of memory 204 ₁ and 204 ₂ may, or may not, be parts of the same physical memory, and both memories 204 ₁ and 204 ₂ may be situated “off-chip”, i.e. not on the same chip as the GPU 202. Communication between the memories (204 ₁ and 204 ₂) and the GPU 202 may take place over a communications bus in the system 200. The graphics processing system 200 is a tile-based deferred rendering system, meaning that the rendering space of the system 200 is divided into a plurality of tiles and that HSR is performed on a fragment prior to performing texturing and/or shading on the fragment in order to render the scene. However, in other examples, graphics processing systems may be non tile-based and/or not deferred rendering systems. The GPU 202 comprises a geometry processing module 206, a tiling module 208 and a rasterization module 210, wherein the rasterization module 210 comprises a hidden surface removal (HSR) module 212 and a texturing/shading module 214. The GPU 202 also comprises a primitive block allocation module 216 which is arranged to allocate primitives to primitive blocks in accordance with their spatial positions. The primitive block allocation module 216 comprises allocation logic 218 and a data store 220. The data store 220 is configured to store a set of primitive blocks 222 _(n) to which primitives can be allocated. In the example shown in FIG. 2, the data store 220 can store up to three primitive blocks 222 ₁ to 222 ₃. In other examples, the data store 220 may have space for storing other numbers of primitive blocks, e.g. up to two or four or more primitive blocks. As a person skilled in the art would appreciate, the graphics processing system 200 shown in FIG. 2 may be part of a larger computer system (e.g. a smart phone, tablet, laptop, PC, TV, set top box, etc.) which, as described below with reference to FIG. 6, may comprise other elements such as a central processing unit (CPU), other memories and other devices (such as a display, speakers, microphone, keypad, etc.) which may be able to communicate with each other, e.g. over a communications bus.

An example of the operation of the graphics processing system 200 is described with reference to the flow chart shown in FIG. 3. Primitives are received at the geometry processing module 206 of the GPU 202 at step S302. The primitives may be received from an application which is running in the same computer system as the GPU. The primitives are received at the GPU 202 as a sequence and the order of the received primitives in the sequence may affect the way in which the primitives will be rendered, for example for translucent primitives.

In step S304, for a current primitive, the allocation logic 218 compares an indication of a spatial position of the current primitive with corresponding indications of the spatial positions of the open primitive blocks 222 ₁ to 222 ₃. Then in step S306 the allocation logic 218 allocates the current primitive to a primitive block (e.g. one of the open primitive blocks 222, or a new primitive block) based on the result of the comparison in step S304. In this way, the current primitive is allocated to a primitive block in accordance with its spatial position. In step S308 the allocation logic 218 determines whether there are more primitives to allocate to primitive blocks, and if there are then steps S304 and S306 are repeated for the next primitive. However, if there are no more primitives to allocate then the method passes from step S308 to step S310 in which the primitive blocks stored in the data store 220 are flushed to the tiling module 208. When further primitives are received at the primitive block allocation module 216 then the method can restart at step S302.

The preceding paragraph explains steps S304 and S306 at a high level, and these steps can be implemented in different ways in different examples, as described in more detail below.

FIG. 4 shows a simple example of a scene 400 to be rendered in the graphics processing system 200. The scene 400 includes two similar objects 402 ₁ and 402 ₂ which are spatially separated from each other in the scene 400. The graphics processing system 200 is a tile-based rendering system which has a rendering space divided into a plurality of tiles. In the simple example shown in FIG. 4, the rendering space is divided into a 4×6 array of rectangular tiles. In other examples the rendering space may be divided into a different number and/or arrangement of tiles. In one example, each tile comprises 32×32 sample positions and there may be many tiles (e.g. hundreds of tiles) in the rendering space, depending upon the size and resolution of the image that is being rendered. In other examples tiles may be non-rectangular (e.g. triangular or hexagonal), or may vary in size according to their position in the rendering space. FIG. 4 also shows two primitives 404 ₁ and 404 ₂ of the object 402 ₁, and two similar primitives 404 ₃ and 404 ₄ of the object 402 ₂. In the example shown in FIG. 4 the primitives are triangles and may each be defined by vertex data at three vertices, but in other examples other types of primitives may be used wherein the primitives may be other shapes such as quadrilaterals or hexagons, or may be lines or points. The application may send the primitives to the graphics processing system 200 in an order that it deems to be suitable, and may for example group similar primitives together such that the primitives 404 ₁, 404 ₃, 404 ₂ and 404 ₄ may be sent one after another, i.e. consecutively in the sequence. As an example, primitives may be “similar”, and therefore grouped together, if they have a similar state. It can therefore be appreciated that the sequence of primitives which is received at the GPU 202 might not have primitives grouped together spatially in the rendering space.

Furthermore, the geometry processing module 206 performs functions such as clipping and culling to remove primitives which do not fall into a visible view. The geometry processing module 206 may also project the primitives into screen-space. The primitives are passed from the geometry processing module 206 to the primitive block allocation module 216, such that the sequence of primitives is received by the allocation logic 218. The operations performed by the geometry processing module 206 may increase the occurrences of primitives, which are close to each other in the sequence of primitives received by the primitive block allocation module 216, being significantly spatially separated over the rendering space 400. If the primitives are placed into primitive blocks in strict sequence order as in the prior art graphics processing system 100, then it is likely that the four primitives 404 ₁ to 404 ₄ would all be placed into the same primitive block. Other primitives of object 402 ₁ may be placed into a different primitive block. Therefore, when the tile in the second row of the second column is processed by the HSR module 112, two primitive blocks would need to be fetched from the memory 104 ₁. In contrast, by grouping primitives together based on their spatial positions (as is done by the primitive block allocation module 216), when the tile in the second row of the second column is processed by the HSR module 212 it may be the case that fewer primitive blocks (e.g. only one primitive block) would need to be fetched from the memory 204 ₁. This reduces the amount of data which needs to be fetched from the memory 204 ₁. It is noted that although the HSR module 212 only needs to fetch the primitives from a primitive block which are visible in a tile, all the header data in the primitive block is needed even if there is only one primitive which is visible in the tile. Therefore for the same number of visible primitives in a tile, a reduction in the number of primitive blocks processed means less header data is fetched and a higher performance can be achieved in HSR module 212. Writing and reading data to and from the memories 204 ₁ or 204 ₂ is a relatively slow process in the processing of primitives by the system 200 especially when the memories are “off-chip”, i.e. not on the same chip as the GPU 202. That is, data transfer between the GPU 202 and the memories 204 ₁ and 204 ₂, e.g. over a communications bus, is usually significantly slower than data transfer between components on the same integrated circuit chip. In tests, the system 200 has a reduction of approximately 10% in the amount of primitive data (which equates to a reduction of approximately 4% in the amount of total data) passed between the GPU 202 and the memory 204 ₁ compared to an equivalent system (e.g. system 100) which does not spatially sort primitives into primitive blocks. The exact figures for the reductions depend upon the properties of the scene being rendered. A reduction such as this in the amount of data passed between the GPU 202 and the memory 204 ₁ can make a significant improvement to the speed and efficiency of the graphics processing system 200.

The primitives received at the primitive block allocation module 216 are processed by the allocation logic 218, e.g. one at a time, to thereby allocate the primitives to primitive blocks. Initially there might not be any open primitive blocks in the data store 220 and when the first primitive is received, a new primitive block 222 ₁ is created and stored in the data store 220 and the primitive is allocated to the new primitive block 222 ₁. After some further primitives have been received, the data store 220 may have a plurality of open primitive blocks (e.g. up to three primitive blocks 222 ₁ to 222 ₃ in the example shown in FIG. 2) to which a primitive can be allocated. A primitive block is “open” if it is not completely full, i.e. such that further primitives can be allocated to it. When a primitive block is filled (e.g. such that it cannot have further primitives allocated to it) then it is flushed, i.e. outputted, from the data store 220 and provided to the tiling module 208. For each open primitive block the primitive block allocation module 216 maintains a bounding box, which is a region in screen space that bounds all the primitives allocated to that primitive block. A bounding box might have many different forms. For example, a bounding box may be rectangular or any other suitable bounding shape, e.g. a polygon or a circle, and a bounding box may, or may not, be aligned with the axes of the image. The resolution of a bounding box may be different in different examples, and may for example be rounded up to the resolution of whole tiles or may have a different (e.g. finer) resolution than the tile resolution. The open primitive blocks 222 ₁ to 222 ₃ stored in the data store 220 at any given time have non-overlapping bounding boxes. That is, the set of open primitive blocks 222 ₁ to 222 ₃ are spatially separated from each other. As described herein, the primitive block allocation module 216 attempts to allocate primitives to primitive blocks such that the primitive blocks remain spatially separated from each other.

A primitive block is a data construct for storing primitive data, which can be stored in a parameter memory, such as memory 204 ₁. FIG. 5 shows an example of a primitive block 500. The primitive block 500 includes a header 502 which includes state information (such as a depth compare mode, a blending state, a texture state, a primitive type, etc.) to describe how the primitives in the primitive block are to be rendered. The primitive block 500 also includes vertex data 504. The vertex data comprises data for each of the vertices of the primitives included in the primitive block 500. In the example shown in FIG. 5 there are n vertices (V₀ to V_(n-1)) and the data for each vertex may include for example a set of coordinates in scene space (i.e. 3D model space), XYZ, to describe the position of the vertex; and a set of attributes to describe the appearance of the vertex, such as texture coordinates (U,V) and/or a base colour to apply to the vertex. The primitive block 500 also includes primitive index data 506. The primitive index data comprises a set of indices (e.g. three indices for triangular primitives) for each of the primitives included in the primitive block 500 to define which of the vertices make up each of the primitives. In the example shown in FIG. 5 there are m primitives (P₀ to P_(m-1)). It is noted that primitives in the primitive block 500 may share vertices, e.g. primitives P1 and P2 (which may correspond to primitives 404 ₁ and 404 ₂ shown in FIG. 4) share two vertices (V₀ and V₂). It can be appreciated that increasing the number of vertices in a primitive block which are shared between multiple primitives will reduce the amount of data of the primitive block. There is a maximum number of vertices (i.e. a vertex threshold) that can be included in a primitive block and/or a maximum number of primitives (i.e. a primitive threshold) that can be included in a primitive block. For example, the vertex threshold may be 64, 256 or some other suitable amount, and the primitive threshold may be 128, 512 or some other suitable amount.

Returning to the process of FIG. 3, the indication of a spatial position of a primitive may comprise a vertex of the primitive. That is, a primitive may include three vertices and the positions of the vertices provide indications of the spatial position of the primitive. Similarly, an indication of a spatial position of a primitive block may comprise a vertex of a primitive included in the primitive block. In this case, the spatial position of a primitive can be compared with the spatial position(s) of the open primitive block(s) 222 by determining whether the primitive has one or more shared vertices with an open primitive block.

If the current primitive shares one or more vertices with a single one of the open primitive blocks 222 then in step S306 the allocation logic 218 allocates the primitive to that primitive block 222. If the current primitive shares one or more vertices with a plurality of the open primitive blocks 222 then in step S306 the allocation logic 218 attempts to merge those primitive blocks, so that the primitive can be allocated to the resulting merged primitive block 222. However, it may not be possible to merge the primitive blocks, if for example the resulting merged primitive block would exceed the maximum allowed number of vertices or the maximum allowed number of primitives that can be included in a primitive block. In this case one of the primitive blocks is flushed from the data store 220 and the current primitive is allocated to the remaining primitive block with which it shares one or more vertices. If the current primitive does not share a vertex with any of the open primitive blocks 222 then the current primitive may be allocated to one of the open primitive blocks 222 based on some other indication of spatial position (e.g. based on the bounding box of the primitive and the bounding boxes of the primitive blocks as described below), or a new primitive block may be opened so that the current primitive can be allocated to the new primitive block.

Another indication of a spatial position is a bounding box, which may be used, e.g. if a primitive has no shared vertices with any of the open primitive blocks. For example, a primitive may have a bounding box within which it is entirely located. Similarly, each of the primitive blocks 222 may have bounding boxes within which all of the primitives within the primitive block are located. The resolution of the bounding boxes may be different in different examples, and may for example be at a per-tile resolution or a per-sample resolution (i.e. at the resolution of the sampling grid). The shape of the bounding boxes may be different in different examples, and may for example be rectangular. The spatial position of a primitive can be compared with the spatial position(s) of the open primitive block(s) 222 by determining whether the bounding box of the primitive overlaps with, or is within a minimum distance from overlapping with, the bounding box of an open primitive block. The minimum distance may for example be 0, 1, 2 or more tiles, and if the bounding box of a current primitive is within the minimum distance from the bounding box of the primitive block then it is treated as though it has an overlapping bounding box with the primitive block.

If a current primitive has an overlapping bounding box with a single one of the open primitive blocks 222 then in step S306 the allocation logic 218 allocates the primitive to that primitive block 222. If the current primitive has an overlapping bounding box with a plurality of the open primitive blocks 222 then in step S306 the allocation logic 218 attempts to merge those primitive blocks, so that the primitive can be allocated to the resulting merged primitive block 222. However, it may not be possible to merge the primitive blocks, if for example the resulting merged primitive block would exceed the maximum allowed number of vertices or the maximum allowed number of primitives that can be included in a primitive block. In this case one of the primitive blocks is flushed from the data store 220 and the current primitive is allocated to the remaining primitive block with which it has an overlapping bounding box.

More generally, if a current primitive has a spatial position which matches the spatial position of a single one of the open primitive blocks (e.g. as indicated by having one or more shared vertices or an overlapping bounding box with the primitive block) then the received primitive is allocated to that primitive block. Furthermore, if a current primitive has a spatial position which matches the spatial position of a plurality of the open primitive blocks (e.g. as indicated by having one or more shared vertices or an overlapping bounding box with the plurality of primitive blocks) then the matching open primitive blocks are merged and/or flushed as appropriate until there is only one matching open primitive block in the data store 220 which has a spatial position matching that of the current primitive and then the current primitive is added to that primitive block. When a primitive is allocated to a primitive block, if the primitive does not lie within the bounding box of the primitive block then the bounding box of the primitive block is updated to include the primitive.

If the spatial position of the current primitive does not match the spatial position of any of the open primitive blocks 222 (e.g. if the bounding box of the primitive does not overlap with, and is not within a minimum distance from overlapping with, the bounding box of an open primitive block) then a new primitive block may be added to the set of open primitive blocks (if possible), such that the current primitive can then be allocated to the new primitive block. However, if the maximum number (e.g. three, in the example shown in FIG. 2) of open primitive blocks are stored in the data store 220 then a new primitive block cannot be created and stored in the data store 220 without flushing one of the primitive blocks from the data store 220. Therefore, if the data store 220 does not have space to store the new primitive block then one of the stored primitive blocks is outputted from the data store 220 to provide space for the new primitive block. This may result in primitive blocks being flushed from the data store 220 before they are completely full. This may mean that more primitive blocks are used than if all of the primitive blocks were completely filled before being flushed, but the benefit of having primitives grouped into primitive blocks based on their spatial positions (such that the primitive blocks have small bounding boxes) normally outweighs any drawback of increasing the number of primitive blocks. In an extreme case when primitives are scattered on screen resulting in many non overlapping primitive blocks each with a few primitives, two of the non overlapping primitive blocks with a low number of primitives (e.g. primitive blocks which are less than half full of primitives) can be merged together rather than flushing one of the primitive blocks. This provides space in the data store 220 to create a new primitive block without flushing too many unfilled primitive blocks.

In alternative examples, a current primitive may be allocated to one of the open primitive blocks 222 (e.g. the closest primitive block) even if the spatial position of the current primitive does not match the spatial position of any of the open primitive blocks 222. In some situations, this may be preferable to flushing a primitive block from the data store 220 and starting a new primitive block.

When one of the open primitive blocks is to be flushed before it is completely filled, e.g. to provide space for adding a primitive block to the data store 220, then a selection is made to determine which one of the open primitive blocks is to be flushed. The selection may be made in accordance with an outputting scheme (or “flushing scheme”). In terms of the sequence order of the primitives, it does not matter which of the open primitive blocks are flushed from the data store 220 because the open primitive blocks are non-overlapping with respect to each other. It is important to maintain the order of primtiives at each particular sample position in the rendering space, but it is not crucial to maintain the ordering of non-overlapping primitives with respect to each other. That is, the relative ordering of primitives which cover a particular sample position should be maintained, but since the open primitive blocks stored in the data store 220 are non-overlapping, any of the open primitive blocks can be flushed without breaking the ordering of primitives at particular sample positions.

When two of the open primitive blocks are merged, the primitives from one of the primitive blocks can be appended to the primitives in the other primitive block to form the primitives in the resulting merged primitive block. There is no need to re-order the primitives within the merged primitive block in accordance with their sequence positions because the open primitive blocks (before merging) were non-overlapping so a simple append operation will not result in a deviation from the sequence order of primitives at any particular sample position in the rendering space.

The flushing scheme could be any suitable scheme for selecting which of the open primitive blocks 222 to flush from the data store 220. For example, the flushing scheme could be:

-   -   (i) a round robin scheme;     -   (ii) an output the biggest scheme in which the primitive block         with the most primitives is selected to be outputted;     -   (iii) an output the smallest scheme in which the primitive block         with the fewest primitives is selected to be outputted;     -   (iv) an output the oldest scheme in which the primitive block         which has been in the data store 220 for the longest amount of         time is selected to be outputted;     -   (v) a merge and output smallest and biggest scheme in which the         primitive block with the most primitives and the primitive block         with the fewest primitives are merged and the resulting merged         primitive block is then selected to be outputted;     -   (vi) a merge threshold scheme in which any primitive blocks with         fewer than a threshold number of primitives are merged and the         resulting merged primitive block is then selected to be         outputted;     -   (vii) a merge smallest scheme in which the two primitive blocks         with the fewest primitives are merged and the resulting merged         primitive block is kept in the data store 220, wherein in this         case one of the primitive blocks 222 is selected to be outputted         only if merging is not possible; or     -   (viii) a combination of any of the above flushing schemes.

Testing was performed to determine which of the flushing schemes provided the best results in terms of the reduction in the amount of parameter data passing between the GPU 202 and the memory 204 ₁, and it was found that the merge smallest scheme (scheme vii) gave the best results.

In some examples, if a render state changes (e.g. if the depth compare mode or type of primitives) changes or if the end of the sequence of primitives for an image is encountered then the open primitive blocks 222 are flushed from the data store 220. This might be inefficient if the render state is changing rapidly (e.g. alternating between two render states), so in some examples a rapidly changing render state can be detected and in this case some primitive blocks might not be flushed when the render state changes to reduce the number of separate primitive blocks that are flushed. The limit on the number of open primitive blocks 222 which can be stored in the data store 220 affects the average fullness of the primitive blocks which are flushed from the data store 220. For example, increasing the number of open primitive blocks 222 which can be stored in the data store 220 will provide more opportunities for allocating a primitive to an open primitive block without needing to flush any primitive blocks from the data store 220, but it will also increase the number of primitive blocks which are flushed before they are completely filled due to render state changes. Increasing the average fullness of the primitive blocks reduces the number of primitive blocks that are used, which thereby reduces the amount of data that is transferred from the GPU 202 to the memory 204 ₁ because each primitive block includes header data. The optimum limit on the number of open primitive blocks is dependent upon the image which is being rendered. Therefore, the primitive block allocation module 216 may dynamically adapt the limit on the number of open primitive blocks 222 which can be stored in the data store 220 based on an analysis of the received primitives. For example, the limit could be set initially at three (as shown in FIG. 2) and if the average fullness of the flushed primitive blocks could be increased by increasing the limit (e.g. if the incoming primitives are widely spatially distributed over the rendering space) then the limit could be increased, e.g. to four. Similarly, if the average fullness of the flushed primitive blocks could be increased by decreasing the limit (e.g. if the rendering state is changing frequently) then the limit could be decreased, e.g. to two. The limit itself may have a maximum which it cannot exceed which may be determined by the amount of on-chip memory. Increasing the maximum value of the limit on the number of open primitive blocks which can be stored in the data store 220 means that the data store needs a greater amount of on-chip memory, which is a very limited resource, so keeping the maximum value of the limit on the number of open primitive blocks 222 which can be stored in the data store 220 low (e.g. less than five) may be advantageous.

Each primitive block has an index map which maps the indices of the vertices in the primitive block to the indices of the vertices sent from the application. When primitive blocks are merged the index map of the merged primitive block will need to be updated to reflect the new indices of the vertices in the merged primitive block accordingly.

The primitive blocks which are outputted from the primitive block allocation module 216 are passed to the tiling module 208 which determines which primitives are present within each of the tiles of the rendering space of the graphics processing system 200. The tiling module 208 determines per-tile display lists which indicate which primitives are present within each of the tiles of the rendering space. The display lists and the primitive blocks are outputted from the tiling module 208 and stored in the memory 204 ₁. The rasterization block 210 fetches the display list for a tile and the primitive blocks relevant to that tile from the memory 204 ₁ and the HSR module 212 performs hidden surface removal to thereby remove fragments of primitives which are hidden in the scene. The remaining fragments are passed to the texturing/shading module 214 which performs texturing and/or shading on the fragments to determine pixel values of a rendered image which can be passed to the memory 204 ₂ for storage in a frame buffer. The rasterization block 210 processes each of the tiles and when the whole image has been rendered and stored in the memory 204 ₂, the image can be outputted from the graphics processing system 200 and, for example, displayed on a display.

The sorting of primitives into primitive blocks based on their spatial locations may result in a greater number of primitive blocks because some primitive blocks are not completely filled before they are flushed from the data store 220, so there may be a slight increase in the amount of primitive data written out from the GPU 202 to the memory 204 ₁ due to an increased number of primitive block headers. However, due to the spatial sorting of the primitives into primitive blocks, primitives included in a primitive block are more likely to share vertices, such that the amount of data used to represent the primitives can be reduced since the shared vertex data need only be stored once in the primitive block. Furthermore, any slight increase in the amount of primitive data written out from the GPU 202 to the memory 204 ₁ is greatly outweighed by a reduction in the amount of primitive data that is read from the memory 204 ₁ by the rasterization module 210 for use by the HSR module 212. That is, since the HSR module 212 operates on a tile, it reads in primitive blocks containing primitives which are relevant to that tile and due to the spatial sorting of primitives into the primitive blocks fewer primitive blocks will be needed to be read from the memory 204 ₁ by the HSR module 212 for performing HSR for a tile. Therefore, the examples described herein are particularly useful when the primitive block allocation module 216 is included as part of a tile-based graphics processing system. However, the spatial grouping of primitives into primitive blocks also improves the cache hit rate for primitives fetched by the HSR module 216 and this is useful for both tile-based and non-tile based rendering systems.

Some pseudo code is presented below as an example of code which can be used to implement the graphics processing system 200:

// Check the current primitive for vertex sharing and overlapping bounding boxes For each of the existing open primitive blocks check if the current primitive has shared vertices or an overlapping bounding box: If number of shared vertices > 0 in the primitive block, then Increase number of overlapping primitive blocks by 1 Increase number of the primitive blocks with shared vertices by 1 Else if the current primitive overlaps the bounding box of the primitive block Increase number of overlapping primitive blocks by 1 End if End for // Add the current primitive into one of the primitive blocks If no primitive block overlaps the current primitive: If the number of existing open primitive blocks = the maximum number of open primitive blocks Flush one of the primitive blocks first, according to a flushing scheme. End if Add the current primitive into an empty primitive block. Else if the current primitive shares vertices or overlaps with only one primitive block: Add the current primitive to that primitive block. Else (the current primitive overlaps with more than one primitive block): If the current primitive has shared vertices with more than one primitive block: If all the primitive blocks that share vertices with the current primitive can be merged into one: Merge all the primitive blocks into one. Else For all the primitive blocks Merge the first two primitive blocks. Flush the first primitive block if cannot merge. Until there is only one primitive block that shares vertices with the current primitive. End if Add the current primitive to the one primitive block. Else ( the primitive overlaps with more than one primitive block): If the primitive shares vertices with one primitive block Let b be the only primitive block sharing vertices with the primitive. Merge all the blocks that overlap the primitive. If a block different from b cannot be merged this way, flush it. Add the current primitive in the one primitive block b. Else (No block with shared vertices) Let M be the set of primitive blocks overlapping the primitive. If it is possible to merge all blocks in M into one single block b, do it. Else Merge all possible couples of block in M; If a block cannot be merged this way, flush it. End If End if Let b be the only primitive block overlapping the primitive. Add the current primitive in the one primitive block b. End if End if End if // Add the primitive to block b If there is no space to add the current primitive in the primitive block b: Flush the primitive block b first. Add the current primitive into the new primitive block. Else Add the primitive to the primitive block b, checking for shared vertices. End if

The allocation logic 218 may be implemented on the GPU 202 in hardware or software or a combination thereof. For example, if the allocation logic 218 is implemented in hardware it may be formed as a particular arrangement of transistors and other hardware components which is suited for performing the desired function of the allocation logic as described herein. In contrast, if the allocation logic 218 is implemented in software it may comprise a set of computer instructions which can be stored in a memory and can be provided to the GPU 202 for execution thereon. Furthermore, although in the examples described herein, the graphics processing system uses a GPU, in other examples a general purpose processing unit, e.g. a CPU, could be used to implement the functionality which is described herein as being implemented on the GPU 202.

The graphics processing system 200 described above can be implemented in a computer system. For example, FIG. 6 shows a computer system which comprises the GPU 202, a CPU 602 and a memory 604, wherein the memory 604 may include memory blocks corresponding to memories 204 ₁ and 204 ₂ described above. The computer system also comprises other devices 606, such as a display 608, speakers 610, a microphone 612 and a keypad 614. The components of the computer system can communicate with each other via a communications bus 616. Computer program code for an application may be stored in the memory 604, and may for example be executed on the CPU 602. If the application needs to render an image of a 3D scene, the primitives can be sent to the GPU 202, and the GPU 202 can render the scene as described above.

Generally, any of the functions, methods, techniques or components described above (e.g. the primitive block allocation module 216 and its components) can be implemented in modules using software, firmware, hardware (e.g., fixed logic circuitry), or any combination of these implementations. The terms “module,” “functionality,” “component”, “block”, “unit” and “logic” are used herein to generally represent software, firmware, hardware, or any combination thereof.

In the case of a software implementation, the module, functionality, component, unit or logic represents program code that performs specified tasks when executed on a processor (e.g. one or more CPUs). In one example, the methods described may be performed by a computer configured with software in machine readable form stored on a computer-readable medium. One such configuration of a computer-readable medium is signal bearing medium and thus is configured to transmit the instructions (e.g. as a carrier wave) to the computing device, such as via a network. The computer-readable medium may also be configured as a non-transitory computer-readable storage medium and thus is not a signal bearing medium. Examples of a computer-readable storage medium include a random-access memory (RAM), read-only memory (ROM), an optical disc, flash memory, hard disk memory, and other memory devices that may use magnetic, optical, and other techniques to store instructions or other data and that can be accessed by a machine.

The software may be in the form of a computer program comprising computer program code for configuring a computer to perform the constituent portions of described methods or in the form of a computer program comprising computer program code means adapted to perform all the steps of any of the methods described herein when the program is run on a computer and where the computer program may be embodied on a computer readable medium. The program code can be stored in one or more computer readable media. The features of the techniques described herein are platform-independent, meaning that the techniques may be implemented on a variety of computing platforms having a variety of processors.

Those skilled in the art will also realize that all, or a portion of the functionality, techniques or methods may be carried out by a dedicated circuit, an application-specific integrated circuit, a programmable logic array, a field-programmable gate array, or the like. For example, the module, functionality, component, unit or logic (e.g. the allocation logic 218) may comprise hardware in the form of circuitry.

Such circuitry may include transistors and/or other hardware elements available in a manufacturing process. Such transistors and/or other elements may be used to form circuitry or structures that implement and/or contain memory, such as registers, flip flops, or latches, logical operators, such as Boolean operations, mathematical operators, such as adders, multipliers, or shifters, and interconnects, by way of example. Such elements may be provided as custom circuits or standard cell libraries, macros, or at other levels of abstraction. Such elements may be interconnected in a specific arrangement. The module, functionality, component, unit or logic (e.g. allocation logic 218) may include circuitry that is fixed function and circuitry that can be programmed to perform a function or functions; such programming may be provided from a firmware or software update or control mechanism. In an example, hardware logic has circuitry that implements a fixed function operation, state machine or process.

It is also intended to encompass software which “describes” or defines the configuration of hardware that implements a module, functionality, component, unit or logic described above, such as HDL (hardware description language) software, as is used for designing integrated circuits, or for configuring programmable chips, to carry out desired functions. That is, there may be provided a computer readable storage medium having encoded thereon computer readable program code for generating a graphics processing unit comprising a primitive block allocation module configured to perform any of the methods described herein, or for generating a graphics processing system comprising any apparatus described herein. That is, a computer system may be configured to generate a representation of a digital circuit from definitions of circuit elements and data defining rules for combining those circuit elements, wherein a non-transitory computer readable storage medium may have stored thereon processor executable instructions that when executed at such a computer system, cause the computer system to generate a graphics processing unit comprising a primitive block allocation module as described herein.

The term ‘processor’ and ‘computer’ are used herein to refer to any device, or portion thereof, with processing capability such that it can execute instructions, or a dedicated circuit capable of carrying out all or a portion of the functionality or methods, or any combination thereof.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims. It will be understood that the benefits and advantages described above may relate to one example or may relate to several examples.

Any range or value given herein may be extended or altered without losing the effect sought, as will be apparent to the skilled person. The steps of the methods described herein may be carried out in any suitable order, or simultaneously where appropriate. Aspects of any of the examples described above may be combined with aspects of any of the other examples described to form further examples without losing the effect sought. 

The invention claimed is:
 1. A computer graphics processing system, comprising: a tiling module configured to determine which primitives are present within each of a plurality of tiles; and a primitive block allocation module for allocating primitives to primitive blocks prior to tiling, the primitive block allocation module being arranged to provide primitive blocks to the tiling module, wherein a primitive block is arranged to store primitive data, the primitive block allocation module comprising: a data store configured to store a set of primitive blocks to which primitives can be allocated; and allocation logic configured to: (a) receive a sequence of primitives, and (b) for each of the received primitives, if at least one primitive block is stored in the data store: (i) compare an indication of a spatial position of the received primitive with at least one indication of a spatial position of the at least one primitive block stored in the data store, and (ii) allocate the received primitive to a primitive block based on a result of the comparison, to thereby allocate the received primitive to a primitive block in accordance with its spatial position, to thereby store primitive data for the received primitive in the primitive block to which the received primitive is allocated.
 2. The computer graphics processing system of claim 1 wherein the data store has a limit on the number of primitive blocks which it can store, wherein the limit is 2, 3 or
 4. 3. The computer graphics processing system of claim 2 wherein the allocation logic is configured to dynamically adapt the limit based on an analysis of the received primitives.
 4. The computer graphics processing system of claim 1 wherein the indication of a spatial position of the received primitive comprises a vertex of the received primitive, and an indication of a spatial position of a primitive block comprises a vertex of a primitive included in the primitive block, wherein the allocation logic is configured to compare vertices of the received primitive and vertices of the primitive blocks stored in the data store to determine whether the received primitive has one or more shared vertices with a primitive block stored in the data store.
 5. The computer graphics processing system of claim 1 wherein the indication of a spatial position of the received primitive comprises a bounding box of the received primitive, and an indication of a spatial position of a primitive block comprises a bounding box of the primitive block, wherein the allocation logic is configured to compare the bounding box of the received primitive and the bounding boxes of the primitive blocks stored in the data store to determine whether the bounding box of the received primitive overlaps with, or is within a minimum distance from overlapping with, the bounding box of a primitive block stored in the data store.
 6. The computer graphics processing system of claim 1 wherein the allocation module is further configured such that, responsive to the received primitive being allocated to a primitive block and if the received primitive does not lie within a bounding box of the primitive block, the bounding box of the primitive block is updated to include the received primitive.
 7. The computer graphics processing system of claim 1 further configured to output a primitive block from the data store if the primitive block is full.
 8. The computer graphics processing system of claim 7 wherein a primitive block is full if at least one of: (i) the number of vertices in the primitive block is greater than or equal to a vertex threshold, and (ii) the number of primitives in the primitive block is greater than or equal to a primitive threshold.
 9. The computer graphics processing system of claim 1 wherein the tiling module is configured to determine per-tile display lists which indicate which primitives are present within each of a plurality of tiles.
 10. The computer graphics processing system of claim 1 wherein the tile-based graphics system further comprises a rasterization block which is configured to implement hidden surface removal and texturing or shading on a per-tile basis using the per-tile display lists.
 11. The computer graphics processing system of claim 1 wherein the indication of a spatial position of the received primitive comprises a bounding box of the received primitive, and an indication of a spatial position of a primitive block comprises a bounding box of the primitive block, wherein the bounding boxes have a per-tile resolution.
 12. A non-transitory computer readable storage medium having stored thereon processor executable instructions that when executed cause at least one processor to process primitives including allocating primitives to primitive blocks at a primitive block allocation module which includes a data store for storing a set of primitive blocks to which primitives can be allocated, wherein a primitive block is configured to store primitive data, the processing of primitives comprising: receiving a sequence of primitives; for each of the received primitives, if at least one primitive block is stored in the data store: (i) comparing an indication of a spatial position of the received primitive with at least one indication of a spatial position of the at least one primitive block stored in the data store; and (ii) allocating the received primitive to a primitive block based on the result of the comparison, such that the received primitive is allocated to a primitive block in accordance with its spatial position, wherein primitive data for the received primitive is stored in the primitive block to which the received primitive is allocated; outputting primitive blocks including allocated primitives from the primitive block allocation module; receiving the outputted primitive blocks at a tiling module; and using the received primitive blocks at the tiling module to determine which primitives are present within each of a plurality of tiles.
 13. A non-transitory computer readable storage medium having stored thereon processor executable instructions that when executed at a computer system for generating a representation of a digital circuit from definitions of circuit elements and data defining rules for combining those circuit elements, cause the computer system to generate a graphics processing unit comprising: (i) a tiling module configured to determine which primitives are present within each of a plurality of tiles, and (ii) a primitive block allocation module which is configured to allocate primitives to primitive blocks prior to tiling, the primitive block allocation module being arranged to provide primitive blocks to the tiling module, wherein a primitive block is arranged to store primitive data, the primitive block allocation module comprising: a data store configured to store a set of primitive blocks to which primitives can be allocated; and allocation logic configured to: (a) receive a sequence of primitives, and (b) for each of the received primitives, if at least one primitive block is stored in the data store: (i) compare an indication of a spatial position of the received primitive with at least one indication of a spatial position of the at least one primitive block stored in the data store, and (ii) allocate the received primitive to a primitive block based on the result of the comparison, to thereby allocate the received primitive to a primitive block in accordance with its spatial position, to thereby store primitive data for the received primitive in the primitive block to which the received primitive is allocated. 